Systems and methods for guiding catheters using registered images

ABSTRACT

Systems and methods for imaging a body cavity and for guiding a treatment element within a body cavity are provided. A system may include an imaging subsystem having an imaging device and an image processor that gather image data for the body cavity. A mapping subsystem may be provided, including a mapping device and a map processor, to identify target sites within the body cavity, and provide location data for the sites. The system may also include a location processor coupled to a location element on a treatment device to track the location of the location element. The location of a treatment element is determined by reference to the location element. A treatment subsystem including a treatment device having a treatment element and a treatment delivery source may also be provided. A registration subsystem receives and registers data from the other subsystems, and displays the data.

RELATED APPLICATIONS

The present application is a continuation-in-part of copending U.S.application Ser. No. 10/012,293.

FIELD OF THE INVENTION

The present inventions relate generally to systems and methods forguiding and locating diagnostic or therapeutic elements on medicalinstruments positioned in a body.

BACKGROUND

The use of invasive medical devices, such as catheters and laparoscopesin order to gain access into interior regions or volumes within the bodyfor performing diagnostic and therapeutic procedures is well known. Insuch procedures, it is important for a physician or technician to beable to precisely position the device, including various functionalelements located on the device, within the body in order to make contactwith a desired body tissue location.

In order to accurately position the device, it is desirable that theshape or configuration of the particular volume be determined, andregistered in a known three-dimensional coordinate system, as well asthe location or locations of sites within the volume identified fortreatment. Current techniques, however, are incapable of determining andregistering the true shape and configuration, as well as the dynamicmovement of a volume, or at the least at a resolution high enough toprovide a physician a comfortable understanding of the volume. Manycurrent techniques use fluoroscopy to generate an image of the targetvolume. These devices only provide two-dimensional information about thevolume, however, rather than the more preferred three-dimensionalinformation. The result is that physicians using fluoroscopy to obtainan image of the volume within which a medical device is guided must relypartly on their own general knowledge of anatomy to compensate for thetwo-dimensional image obtained by the fluoroscope. In addition, not onlydo these device not give the physician a three-dimensional view of thevolume, but also do not give an understanding of possible obstacles ormovements within the volume itself, such as the opening and closing ofvalves, atrio-septal defects, atrio-septal defect closure plugs, and thelike.

Some technologies are capable of generating and registeredthree-dimensional images, but these devices are typically incapable ofproducing a high resolution image of the interior space of the volume,since they operate from outside of the body, or from a location outsideof the target volume itself, in the case of transthoracic ortransesophageal echography used to image the heart.

Therefore, it would be desirable to provide systems and methods forguiding a medical device that are able to generate higher resolutionimages of the target volume such that a physician is able to compensatefor any obstructions or physical landmarks within the volume itself

SUMMARY OF THE INVENTION

The present inventions relate generally to systems and methods forguiding and locating diagnostic or therapeutic elements on medicalinstruments positioned in a body by reconstructing a three-dimensionalrepresentation of a subject volume, displaying the representation withor without mapping data, and guiding a device, such as, e.g., atreatment device, by reference to the representation, the mapping data,if available, and the current position of the treatment device withinthe volume.

In accordance with a first aspect of the present inventions, a method ofperforming a procedure in a body cavity of a patient, such as a heartchamber, comprises generating three-dimensional image data of the bodycavity, generating optional three-dimensional mapping data of the bodycavity, registering the image and optional mapping data in athree-dimensional coordinate system, displaying a three-dimensionalimage of the body cavity based on the registered image data, anddisplaying an optional three-dimensional map of the body cavity based onthe registered mapping data. The three-dimensional map is preferablysuperimposed over the three-dimensional image. In one procedure, thethree-dimensional image data is generated from within the body cavity,and is also generated ultrasonically. Also, the three-dimensional imagedata preferably comprises a plurality of two-dimensional data slices. Invarious procedures, the three-dimensional image data or thethree-dimensional mapping data, or both, is dynamically displayed. Afunctional element is moved within the body cavity by registering themovement of the functional element in the coordinate system, anddisplaying the movement by superimposing the element over thethree-dimensional image and optional map. The treatment element isguided by reference to the display, and a target site is treated, suchas by ablation, using the treatment element.

The image data can be registered in a variety of ways. For example, aposition of a source of the image data within the three-dimensionalcoordinate system can be determined, and then the image data can bealigned so that the image data source is coincident with the determinedposition. Or fiducial points within the image data can be generated,positions of the fiducial points within the three-dimensional coordinatesystem can be determined, and then the image data can be aligned so thatthe fiducial points are coincident with the determined positions. Or aset of points can be generated, positions of the points within thethree-dimensional coordinate system can be determined, and then theimage data can be best fit to the set of points. Registration of theimage data can even be accomplished at least partially with userintervention.

In a second aspect of the present invention, a method of performing aprocedure within a body cavity, such as a heart chamber, comprisesinternally generating image data, generating mapping data, andregistering and displaying the image and mapping data in athree-dimensional coordinate system. In one procedure, both the imageand mapping data is three-dimensional. In another procedure, both theimage and mapping data is four-dimensional. Preferably, the image datais generated ultrasonically, and comprises a plurality oftwo-dimensional data slices. A functional element or a treatment elementis moved within the body cavity, the movement is registered in thethree-dimensional coordinate system, and subsequently displayed. Thefunctional or treatment element is then guided by reference to thedisplay, and treatment is delivered to a target site, such as, byablating the site.

In a third aspect of the present invention, a method of performing aprocedure within a body cavity, such as a heart chamber, comprisesinternally generating image data and registering the data in athree-dimensional coordinate system. The image data is preferablythree-dimensional. Also, the image data is preferably generated overtime and dynamically displayed. In one procedure, the image data isgenerated ultrasonically, and is a plurality of two-dimensional slices.A functional element is moved within the body cavity, and the movementis registered in the coordinate system and displayed.

In a fourth aspect of the present invention, a method of performing aprocedure within a body cavity, which may be a heart chamber, comprisesintroducing an imaging probe with an imaging element and a firstlocation element into the body cavity, generating image data,introducing a mapping probe having one or more mapping elements and asecond location element, generating mapping data, determining thelocations of the location elements in a three-dimensional coordinatesystem, registering the image and mapping data in the three-dimensionalcoordinate system based on the locations of the location elements, anddisplaying the registered image and mapping data. The imaging elementpreferably includes an ultrasound transducer. The location elements mayinclude an array of magnetic sensors, or an ultrasound transducer, whichmay be wired or wireless. Preferably, the first location element isadjacent the imaging element, and the second location element isadjacent the mapping elements. Additionally, a roving probe having afunctional element, or a treatment probe having a treatment element, anda third location element is introduced into the body cavity, thelocation of the third location element in the coordinate system isdetermined, the location is registered and displayed, and the functionalelement, or treatment element, is navigated by reference to the display.In one embodiment, the functional element or treatment element is anablation electrode.

In a fifth aspect of the present invention, a method of performing aprocedure within a body cavity, such as a heart chamber, comprisesintroducing an imaging probe having an imaging element and a firstlocation element in to the body cavity, generating image data, removingthe imaging probe, introducing a mapping probe having one or moremapping elements and a second location element into the body cavity,generating mapping data, introducing a roving probe having a functionalelement and a third location element into the body cavity, determiningthe locations of the location elements in a three-dimensional coordinatesystem, registering and displaying the image data, mapping data, andlocations of the functional element in the coordinate system based onthe locations of the location elements, and navigating the treatmentelement by reference to the display while the imaging probe is removedfrom the body cavity. The mapping probe may or may not be removed priorto, or while the roving probe is being deployed or used. The rovingprobe or mapping probe may be introduced into the body cavity while theimaging probe is removed. The location elements may include an array ofmagnetic sensors, or an ultrasound transducer, which may be wired orwireless. Preferably, the first location clement is adjacent the imagingelement, the second location element is adjacent the mapping elements,and the third location element is adjacent the functional element. Theimaging element is preferably an ultrasound transducer. In oneprocedure, the roving probe is a treatment probe and the functionalelement is a treatment element. Here, the treatment element is guided toa target site by reference to the display, and the target site istreated with the treatment element. In one embodiment, the treatmentelement is an ablation electrode.

In a sixth aspect of the present invention, a system for treating atarget site within a body cavity, which may be a heart chamber,comprises an imaging subsystem having an imaging device with an imagingelement and image processing circuitry coupled to the imaging element, amapping subsystem having a mapping device with one or more mappingelements coupled to map processing circuitry, a treatment deliverysubsystem having a treatment device with a treatment element coupled toa treatment delivery source, and a three-dimensional coordinateregistration subsystem comprising registration processing circuitrycoupled to the image and map processing circuitry, three locationelements respectively located on the imaging, mapping, and treatmentdevices, and location processing circuitry coupled between the locationelements and the registration processor. In one embodiment, the threelocation elements are respectively located adjacent the imaging,mapping, and treatment elements. The registration processing circuitryand the location processing circuitry may be integrated into a singleprocessor. Also, the registration, location, image, and mappingprocessing circuitry may all be embodied in a single processor. In oneembodiment, the location elements comprise three orthogonal arrays ofmagnetic sensors. Here, the registration subsystem includes an antenna,a magnetic field generator coupled between the antenna and the locationprocessing circuitry, and a magnetic field detector coupled between thelocation sensors and the location processing circuitry. In anotherembodiment, the location elements comprise an ultrasound transducer.With this embodiment, the location processing component includesultrasound transducers, a first ultrasound transceiver coupled betweenthe ultrasound transducers and the location processing circuitry, and asecond ultrasound transceiver coupled between the ultrasound transducersand the location processing circuitry.

A display is preferably coupled to the registration subsystem. Theimaging element may be an ultrasound transducer, and the imaging devicemay be an imaging catheter. In one embodiment, the treatment element isan ablation electrode, and the treatment delivery source comprises anablation energy source.

In a seventh aspect of the present invention, a system for treating atarget site within a body cavity, which may be a heart chamber, includesan imaging subsystem having an imaging catheter with an imaging elementand image processing circuitry coupled to the imaging element, and athree-dimensional coordinate registration subsystem having registrationprocessing circuitry coupled to the image processing circuitry, alocation element on the imaging catheter, and location processingcircuitry coupled between the location element and the registrationprocessing circuitry. The system also includes a mapping subsystemhaving a mapping device with one or more mapping elements coupled to mapprocessing circuitry. The registration processing circuitry is coupledto the map processing circuitry, and also includes another locationelement on the mapping device coupled to the location processingcircuitry. The location element on the imaging catheter is preferablyadjacent the imaging element. In one embodiment, the location elementincludes an orthogonal array of magnetic sensors, and the registrationsubsystem includes an antenna, a magnetic field generator coupledbetween the antenna and the location processing circuitry, and amagnetic field detector coupled between the magnetic sensors and thelocation processing circuitry. In another embodiment, the locationelement includes an ultrasound transducer, and the registrationsubsystem includes one or more ultrasound transducers, a firstultrasound transceiver coupled between the one or more ultrasoundtransducers and the location processing circuitry, and a secondultrasound transceiver coupled between the ultrasound transducer and thelocation processing circuitry.

In one embodiment, the imaging element comprises an ultrasoundtransducer, and the imaging catheter is coupled to a pullback device. Inone embodiment, the registration processing circuitry and the locationprocessing circuitry are integrated into a single processor. A displayis included that is coupled to the registration subsystem.

In an eighth aspect of the present inventions, a system for treating atarget site within a body cavity, which may be a heart chamber, includesan imaging subsystem comprising an imaging device configured forgenerating image data of the body cavity, a probe configured to be movedwithin the body cavity, and a three-dimensional coordinate registrationsubsystem configured for registering the image data and the location ofthe probe within a three-dimensional coordinate system. The probe maybe, e.g., a treatment device having a treatment element, in which case,the system may further comprise a treatment delivery subsystemcomprising the treatment device and a treatment delivery source coupledto the treatment element. Or the probe may be, e.g., a mapping deviceconfigured for generating mapping data, in which case, the system maycomprise a mapping subsystem comprising the mapping device, wherein theregistration subsystem is further configured for registering the mappingdata within the three-dimensional coordinate system. The system mayfurther comprise a display coupled to the registration subsystem. Theimaging device can take various forms. For example, the imaging devicecan be an internal imaging device, e.g., a real time 3-D imagingcatheter, or an external imaging device, e.g., a computerized axialtomography device or magnetic resonance imaging device. The registrationsubsystem can register the image data within the three-dimensionalcoordinate system in a variety of ways, including using the registrationsteps described above.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to better appreciate how the above-recited and other advantagesand objects of the present inventions are obtained, a more particulardescription of the present inventions briefly described above will berendered by reference to specific embodiments thereof, which areillustrated in the accompanying drawings. Understanding that thesedrawings depict only typical embodiments of the invention and are nottherefore to be considered limiting of its scope, the invention will bedescribed and explained with additional specificity and detail throughthe use of the accompanying drawings in which:

FIG. 1 is a block diagram of one preferred embodiment of a treatmentsystem constructed in accordance with the present inventions;

FIG. 2 is a block diagram of an imaging subsystem used in the treatmentsystem of FIG. 1;

FIG. 3 is a block diagram of a mapping subsystem used in the treatmentsystem of FIG. 1;

FIG. 4 a is a block diagram of a treatment delivery subsystem used inthe treatment system of FIG. 1;

FIG. 4 b is an isometric view of the treatment delivery subsystem ofFIG. 4 a;

FIG. 5 is a block diagram of a magnetic locating portion of aregistration subsystem used in the treatment system of FIG. 1;

FIG. 6 is a block diagram of an ultrasonic locating portion of aregistration subsystem used in the treatment system of FIG. 1;

FIG. 7 a is a schematic diagram showing the operation of the imagingsubsystem and the FIG. 5 registration subsystem within the heart of apatient;

FIG. 7 b is a schematic diagram showing the operation of the imagingsubsystem and the FIG. 6 registration subsystem within the heart of apatient;

FIG. 8 a is a schematic diagram showing the operation of the mappingsubsystem and the FIG. 5 registration subsystem within the heart of apatient;

FIG. 8 b is a schematic diagram showing the operation of the mappingsubsystem and the FIG. 6 registration subsystem within the heart of apatient;

FIG. 9 a is a schematic diagram showing the operation of the treatmentdelivery subsystem and the FIG. 5 registration subsystem within theheart of a patient;

FIG. 9 b is a schematic diagram showing the operation of the treatmentdelivery subsystem and the FIG. 6 registration subsystem within theheart of a patient;

FIG. 10 is an illustration of a reconstructed three-dimensional imagehaving superimposed thereon three-dimensional mapping data; and

FIG. 11 is an illustration of a reconstructed three-dimensional imagealong with three-dimensional mapping data wherein the mapping data ispresented in varying colors; and

FIG. 12 is a block diagram of another preferred embodiment of atreatment system constructed in accordance with the present inventions.

DETAILED DESCRIPTION

The present invention provides a system for generating athree-dimensional image of a volume, registering that image in athree-dimensional coordinate system, generating mapping data of thevolume, registering the positional data to the three-dimensionalcoordinate system, and guiding a treatment device to a target siteidentified by the positional data. The system is particularly suited forreconstructing and mapping a volume within a heart, and for ablatingheart tissue. Nevertheless, it should be appreciated that the inventionis applicable for use in other applications. For example, the variousaspects of the invention have application in procedures for ablating orotherwise treating tissue in the prostate, brain, gall bladder, uterus,esophagus and other regions of the body. Additionally, it should beappreciated that the invention is applicable for use in drug therapyapplications where a therapeutic agent is delivered to a targeted tissueregion. One preferred embodiment of a treatment system 100, shown inFIG. 1, generally includes a registration subsystem 102, an imagingsubsystem 120, a mapping subsystem 140, a treatment delivery subsystem160, memory 104, and a display 106.

The imaging subsystem 120 includes an imaging device or device 122 witha distally located imaging element 124, and an image processor 126coupled to the imaging element 124.. The embodiment of the imagingsubsystem 120 shown in FIG. 1 uses a pullback approach and, therefore,further includes a drive unit 127. As will be described in furtherdetail below, the image processing subsystem 120 gathers data regardingthe subject volume that is detected by the imaging device 122, andprocessed by the image processor 126, and relays that data to theregistration subsystem 102, and specifically a registration processor110. The registration processor 110, with the assistance of a locationprocessor 108 and a location element 128 associated with the imagingelement 124, registers the image data in a three-dimensional coordinatesystem, stores the registered image data in memory 104, and subsequentlydisplays the registered image data on display 106 as a reconstructedthree-dimensional image.

The mapping subsystem 140 includes a mapping device 142 with distallylocated mapping elements 144, and a map processor 146 coupled to themapping elements 144. Reference herein will be made to a mappingcatheter 142 and mapping device 142 interchangeably, but it will beappreciated that the mapping device 142 is not limited to catheters. Themapping subsystem 140 gathers positional data within the subject volumethat correspond to specific target sites identified for treatment, usingdata gathered by the mapping catheter 142 and processed by the mapprocessor 146, and provides the mapping data to the registrationprocessor 110 of the registration subsystem 102. The registrationprocessor 110, with the assistance of the location processor 108 and alocation element 148 associated with the mapping elements 144, registersthe mapping data in a three-dimensional coordinate system, stores theregistered target side data in memory 104, and subsequently displays theregistered mapping data, along with the registered image data, ondisplay 106. The treatment delivery subsystem 160 has a treatment device162 with a distally located treatment element 164, and a treatmentdelivery source 166 coupled to the treatment element 164. The treatmentdevice 162, as shown, is a deployable, invasive treatment device 162,such as an ablation catheter, but the treatment device 162 may be anyother catheter, surgical device, diagnostic device, measuringinstrument, or laparoscopic probe, and is not limited to any particulartype of invasive device. The treatment delivery source 166 is anablation power source when the treatment device 162 is an ablationcatheter. In this case, the treatment element 164 is an ablationelectrode. The registration processor 110, with the assistance of thelocation processor 108 and a location element 168 associated with thetreatment element 164, registers the location of the treatment element164 in a three-dimensional coordinate system, and subsequently displayslocation of the treatment element 164, along with the registered imagedata and mapping data, on display 106.

In one embodiment, the registration processor 110 and the locationprocessor 108 are incorporated into a single processor. In anotherembodiment, the registration processor 110, the location processor 108,the image processor 126, and the map processor 146 are all incorporatedinto a single processor.

The various components of the system 100 will now be discussed ingreater detail.

1. Imaging Subsystem

The imaging subsystem 120 of the system 100 is used to generate arepresentation, preferably a three-dimensional representation or image,of the subject volume. One embodiment of the imaging subsystem 120 ofthe present invention utilizes ultrasound to generate an image of thesubject volume. As illustrated in FIG. 2, this embodiment of the imagingsubsystem 120 includes the imaging device 122, which is used forgathering images from inside the body. In the illustrated embodiment,the imaging device 122 is an intracardiac device. As illustrated in FIG.2, the imaging device 122 is a telescoping catheter that generallyincludes a hollow, outer sheath 21 and a hollow, inner shaft 23.Alternatively, the outer sheath 21 can be a stand-alone element thatdoes not form a part of the imaging catheter 122. A rotatable drivecable 22 extends through the outer sheath 21 and has an imaging element124 mounted at its distal end. Here, the imaging element 124 is anultrasonic transducer. For purposes of describing this embodiment of theimaging subsystem, the imaging element 124 will also be referred to asan ultrasonic transducer 124. The transducer 124 preferably includes oneor more piezoelectric crystals formed of, for example, barium titillateor cinnabar. Other types of ultrasonic crystal oscillators can also beused. For example, organic electrets such as polyvinylidene difluorideand vinylidene fluoride-trifluoro-ethylene copolymers can also, be usedin the ultrasonic transducer 124. The reduced diameter, inner cathetershaft 23 extends through the outer sheath 21, and is attached to thedrive unit 127. The drive cable 22 extends through the inner shaft 23and is engaged to a motor drive shaft (not shown) within the drive unit127. Exemplary preferred imaging device constructions usable with thepresent invention may be found in U.S. Pat. No. 5,000,185, U.S. Pat. No.5,115,814, U.S. Pat. No. 5,464,016, U.S. Pat. No. 5,421,338, U.S. Pat.No. 5,314,408, and U.S. Pat. No. 4,951,677, each of which is expresslyand fully incorporated herein by reference.

As illustrated in FIG. 2, the image subsystem 120 implements a pullbackapproach using the drive unit 127 to longitudinally translate, the innershaft 23, and thus, the drive cable 22 and associated imaging element124 (and specifically, an ultrasound transducer), in relation to theouter sheath 21. The drive unit 127 also rotates the ultrasoundtransducer 124′ (e.g., at thirty or sixty revolutions a minute), suchthat the imaging device 122 is able to retrieve image data representingtwo-dimensional slices of the subject volume. An exemplary preferreddrive unit, and methods for using the drive unit, is disclosed in U.S.Pat. No. 6,292,681, which is fully and expressly incorporated herein byreference.

The image processor 126 generally comprises a processor unit 125, atransmitter 121, and a receiver 123. The processor unit 125 activatesthe transmitter 121 such that the transmitter 121 generates voltagepulses, which may be in the range of 10 to 150 volts, for excitation ofthe transducer 124. The voltage pulses cause the transducer 124 toproject ultrasonic waves into the subject volume. As discussed, theillustrated imaging subsystem 120 is operated using a pullback method.Therefore, the drive unit 127 rotates the transducer 124 and pulls backthe transducer 124 proximally towards the drive unit 127 as thetransducer is projecting ultrasonic waves into the volume. As a result,the imaging subsystem 120 is able to gather two-dimensional slices ofimage data for the volume. In a preferred embodiment, the gathering ofthe two-dimensional slices of image data is gated, e.g., the gatheringof image slices is timed relative to cardiac activity or to respiration,and each slice is gathered at substantially the same point in the heartor the respiration cycles. The two-dimensional slices are ultimatelyaggregated to form a reconstructed, three-dimensional image of thevolume. In another embodiment, slices of image data are gathered in setsof slices, such as, sets of thirty or sixty slices. With thisembodiment, corresponding slices in each set are matched together inorder to form a reconstructed, four-dimensional image of the volume(i.e., a dynamic three-dimensional image that moves over time, e.g., forshowing the beating of the heart). For example, the first slices of eachset are grouped and displayed together, the second slices of each setare grouped and displayed together, and so on. Tissue, including tissueforming anatomic structures, such as heart, and internal tissuestructures and deposits or lesions on the tissue, will scatter theultrasonic waves projected by the transducer 124. The scatteredultrasonic waves return to the transducer 124. The transducer 124converts the scattered ultrasonic waves into electrical signals andrelays the signals to the receiver 123. The receiver 123 amplifies theelectrical signals and subsequently relays the amplified signals to theprocessor unit 125.

The processor unit 125 digitally processes the signals using knownalgorithms, such as, e.g., conventional radar algorithms. One suitablealgorithm that the processor unit 125 may used is based upon the directrelationship that elapsed time (At) between pulse emission and returnecho has to the distance (d) of the tissue from the transducer isexpressed as follows: d=Δt/2v, where v is the speed of sound in thesurrounding media. After processing the signals, the processor unit 125transmits the processed signals, i.e., the image data, to theregistration processor 110 of the registration subsystem 102.

As an alternative to the pull back approach, the transducer 124 may beoperated without rotation such as in a phased-array arrangement, asshown in U.S. Pat. No. 4,697,595, U.S. Pat. No. 4,706,681, and U.S. Pat.No. 5,358,148, which are all hereby fully and expressly incorporatedherein by reference. With the phased-array arrangement, each gatheredimage is a full image of the volume, rather than the two-dimensionalslices gathered using the pull back approach. In this case, afour-dimensional image can be generated simply by operating thephased-array arrangement over time.

A location element 128 is also provided on the distal end of the imagingdevice 122, and specifically, the distal end of the shaft 23, such thatit follows the axial movement of the ultrasound transducer 124 whenpulled back. Preferably, the location element 128 is placed adjacent theultrasound transducer 124. The location element 128 is coupled to alocation processor 108, which receives data regarding the location,including orientation, of the location element 128 within the subjectvolume. The location processor 108 transmits the location data to theregistration processor 110. Details of the location processor 108 willbe discussed herein.

2. Mapping Subsystem

The mapping subsystem 140 is utilized to identify' a target site orsites for treatment within the subject volume. For example, the mappingsubsystem 140 is used to locate aberrant conductive pathways, i.e.,target sites, within the heart. The aberrant conductive pathwaystypically constitute irregular patterns called dysrhythmias. Here, themapping subsystem 140 identifies regions along these pathways, calledfoci, which are then ablated using the treatment delivery subsystem 160to treat the dysrhythmia.

FIG. 3 illustrates one preferred embodiment of the mapping subsystem140. The mapping subsystem 140 includes the map processor 146 coupled tothe mapping device 242. The mapping device 142 has a catheter body 143with distal and proximal ends. On the proximal end, a handle (not shown)is provided that includes connectors (not shown) to couple the mappingdevice 142 with the map processor 146.

The distal end of the mapping device 142 includes a structure 145 thatcarries the mapping elements 144. The mapping elements 144 arepreferably electrodes. The embodiment in FIG. 3 includes athree-dimensional mapping element carrying structure 145 that takes theform of a basket. The structure 145 may, however, have any configurationthat is suitable for carrying mapping elements 144, such as a helicalstructure or a linear structure. Alternatively, the structure 145 maycomprise several catheters, rather than the one shown in FIG. 3. Thesemultiple catheters may be distributed in any configuration suitable forthree-dimensional mapping. As shown, the structure 145 comprises a basemember 151 and an end cap 153. Generally flexible splines 141 extend ina circumferentially spaced relationship between the base member 151 andthe end cap 153, and also define a space 149. The splines 148 arepreferably connected between the base member 151 and the end cap 153 ina resilient, pretensed condition. Therefore, the splines 141 arepreferably constructed from a resilient, inert material such as Nitinolmetal or silicone rubber. In one embodiment, eight splines 141 form thebasket structure 145. It should be appreciated that either additional orfewer splines 141 may be utilized depending on the particularapplication. Additionally, in the illustrated embodiment, each spline141 is shown as carrying eight mapping elements 144. It should likewisebe appreciated that additional or few mapping elements 144 may becarried on each spline 141.

A sheath 147 is provided that is slidable over the catheter body 143 ofthe mapping device 142. The sheath 147 has an inner diameter that isgreater than the outer diameter of the catheter body 143. The sheath 147may be manufactured from a biocompatible plastic material, such as,e.g., polyurethane. The sheath 147 is slidable distally to cover, i.e.,capture and collapse, the structure 145, thereby resulting in a lowerprofile for the mapping device 142. When the sheath 147 covers thestructure 145, the lower profile of the mapping device 142 facilitatesthe introduction and placement of the structure 145 within the subjectvolume. When desired, the sheath 147 is slid proximally to remove thecompression force the sheath 147 was placing on the structure 145. As aresult, the structure 145 opens to assume its uncompressed shape, which,in the illustrated embodiment, is a basket shape. Other devices are alsocapable of being inserted into the subject volume by using the sheath147, including the imaging device 122 and the treatment device 162, aswill be described in further detail below.

When the mapping device 142 is deployed within, e.g., the heart chamber,the structure 145 holds the mapping elements 144 against the endocardialsurface. The resilient nature of the splines 141 of the structure 145enables the splines 141 to conform and bend to the tissue they contact,thereby placing the mapping elements 144 in direct contact with bodytissue. The mapping elements 144 then detect data from the tissue thatis used to identify target sites for treatment. In the illustratedembodiment, the mapping elements 144 record the electrical potentials inmyocardial tissue. Signals corresponding to the recorded electricalpotentials are transmitted to the map processor 146.

The map processor 146, in turn, derives the activation times, thedistribution, and the waveforms of the potentials recorded by themapping elements 144, using known algorithms, to determine any irregularelectrical potentials. After the map processor 146 identifies theirregular electrical potentials, the map processor 146 identifies whichparticular mapping element 144 recorded a specific, irregular electricalpotential. An irregular electrical potential corresponds to a targetsite, and the mapping element 144 that recorded that potential is themapping element 144 nearest the target site. Thus, the map processor 146identifies a target site by identifying an irregular electricalpotential, identifying the mapping element 144 that recorded thepotential, and identifying the target site within the subject volume byreference to that mapping element 144. The map processor 146 thentransmits the localized mapping data to the registration processor 110of the registration subsystem 102. Further details for the deploymentand structures of the mapping subsystem 140 are described in U.S. Pat.No. 5,636,634 and U.S. Pat. No. 6,233,491, all of which are hereby fullyand expressly incorporated herein by reference. Also, further detailsfor systems and methods for the determination of irregular electricalpotentials in order to identify target sites for treatment are describedin U.S. Pat. No. 6,101,409, U.S. Pat. No. 5,833,621, U.S. Pat. No.5,485,849, and U.S. Pat. No. 5,494,042, all of which are hereby fullyand expressly incorporated herein by reference.

Additionally, location elements 148 are provided on the structure 145,which each location element 148 in close proximity or adjacent a mappingelement 144. The location elements 148 are coupled to the locationprocessor 108, which receives data regarding the location, includingorientation, of each location element 148 within the subject volume.Alternatively, rather than mounting the location element 148 on themapping device 142, the location element 148 can be located on a rovingprobe. In this case, the locations of the mapping elements 144 can bedetermined by determining the proximity between the location element 148on the roving probe and one or more mapping elements 144. Furtherdetails on the use of a roving probe mounted location element to locateand register mapping elements are disclosed in U.S. patent applicationSer. No. ______ (Attorney Docket No. 258/208), entitled “Systems andMethods for Guiding and Locating Functional Elements on Medical DevicesPositioned in a Body,” and filed on Oct. 24, 2001, which is fully andexpressly incorporated herein by reference.

The location processor 108 transmits the location data to theregistration processor 110. Details of the location processor 108 willbe discussed herein.

3. Treatment Delivery Subsystem

The treatment delivery subsystem 160 is utilized to treat the targetedsites identified by the mapping subsystem 140. As illustrated in FIGS. 4a and 4 b, a preferred embodiment of the treatment delivery subsystem160 includes the treatment device 162, that is an ablation catheter,coupled to the treatment delivery source 166. More particularly, thetreatment delivery source 166 is coupled to the treatment element 164disposed on a distal end of the treatment device 162. The treatmentdelivery source 166 is an ablation power generator that includes anablation power source 163, and the treatment element 164 is an ablationelement. In one preferred embodiment, the treatment device 162 is asteerable catheter as described in U.S. Pat. No. 6,233,491, which hasbeen fully and expressly incorporated by reference herein. Accordingly,the treatment device 162 shown in FIG. 4 b includes a steering component71 mounted on a handle 73. A cable 75 connects a proximal end of thehandle 73 to the treatment delivery source 166.

Also, the treatment device 162 preferably includes a temperature sensor167 located near the treatment element 164. When ablation energy isused, the temperature sensor 167 facilitates the delivery of ablationenergy to a target site by gathering and transmitting temperature datafor the target site to the treatment delivery source 166. A temperaturegauge 68 displays the temperature data. Alternatively, the registrationsubsystem 102 may display the temperature of the tissue surrounding thetarget site to the user on the display 106.

The ablation energy delivered by the ablation power source 163 is usedto ablate target sites identified using the mapping subsystem 140 byheating the targeted tissue. The ablation power source 163 is preferablya radio frequency (RE) generator. Any suitable ablation power source 163may be utilized, however, including, e.g., a microwave generator, anultrasound generator, a cryoablation generator, and a laser or otheroptical generator. In the illustrated embodiment, the treatment deliverysource 166 delivers radio frequency energy to the treatment element 164in a controlled manner. To this end, the treatment delivery source 166comprises a control circuit 161 that controls the amount of ablationenergy delivered by the ablation power source 163 to the treatmentelement 164, and a temperature circuit 169 for facilitating the input oftemperature sensing data from the temperature sensor 167 into thecontrol circuit 161. A power control input 65 is used by the user to setthe ablation energy desired to be delivered by the treatment deliverysource 166. A clock 165 is also provided to track the time elapsedduring the delivery of ablation energy, and a counter 69 is provided todisplay the elapsed time. A timer input 66 is coupled to the clock 165,and allows a user to input the desired time of delivery of energy. Theactual ablation energy delivered by treatment delivery source 166 isreported by a power meter 61. Also, an impedance meter 64 coupled to thecontrol circuit 161 measures contact between the treatment element 164and tissue. An ablation power control button 62 allows the user to placethe source 166 in a power “on” or “off” orientation. Further details onthe use and structure of a suitable treatment delivery source usingablation energy are disclosed in U.S. Pat. No. 5,383,874 to Jackson, etal., which is expressly and fully incorporated herein by reference.

A location element 168 is provided on the distal end of the treatmentdevice 162, and preferably in close proximity or adjacent to thetreatment element 164. Also, the location element 168 may beincorporated into the treatment element 164, thereby eliminating theneed for a physically separate location element 168. The locationelement 168 is coupled to the location processor 108 and provides dataregarding the location, including orientation, of the location element168 within the subject volume to the location processor 108. Thelocation processor 108 transmits the location data to the registrationprocessor 110. Details of the location processor 108 will be discussedherein.

4. Registration Subsystem

The registration subsystem 102 of the system 100 includes the locationprocessor 108, registration processor 110, and the location elements128, 148, and 168. The location processor 108 is preferably incorporatedinto the registration subsystem 102, but may be a stand-alone subsystemthat is coupled to the registration subsystem 102. In either case, thelocation processor 108 is coupled to the registration processor 110 ofthe registration subsystem 102. The location elements 128, 148, and 168can be electrically coupled to the location processor via wires.Alternatively, wireless location sensors, such as, e.g., electromagneticor magnetic resonant transducers, electronic emitters, infra- ornear-infrared emitters, can be used as any of the location elements 128,148, or 168. In this case, a link between the location elements 128,148, or 168 and the location processor 108 can be a wireless link. Forany of the location elements 128, 148, or 168, the location processor108 may use ultrasound, magnetic fields, or optical means, to track theposition of any of the location elements 128, 148, or 168 with respectto the three-dimensional coordinate system, thereby enabling theregistration of the image data, mapping data, or location of thetreatment element 164, respectively, to the three-dimensional coordinatesystem.

The location processor 108 processes and provides position specificinformation in various ways. In the embodiment shown in FIG. 5, thelocation processor 108 utilizes ultrasound to determine the absolutelocation of a location element 168(1) within the three-dimensionalcoordinate system of the subject volume. Here, the location element168(1) is an ultrasonic transducer. Suitable transducers include, butare not limited to, phased array transducers, mechanical transducers,and piezoelectric crystals. Triangulation techniques are utilized inorder to render an absolute location, including orientation, of thelocation element 168(1) with respect to the three-dimensional coordinatesystem. Since the location element 168(1) is placed in close proximityto the treatment element 164, or is incorporated into the treatmentelement 164, the absolute location including orientation of thetreatment element 164 is also determined.

To determine the absolute location of the location element 168(1), thetime of-flight of a sound wave transmitted from the location element168(1) relative to reference transducers 202 located on referencecatheters 204 may be determined. The reference transducers 202, insteadof being disposed on catheters, may alternatively be placed at otherlocations in or on the body, such as, e.g., on a patient's chest or atfixed points away from the body. Additionally, although three referencetransducers 202 are illustrated in FIG. 5, both a smaller number or alarger number of reference transducers may be utilized.

In embodiments of the location processor 108 having referencetransducers 202 that are disposed on reference catheters 204, thereference catheters 204 may be placed at locations outside the subjectvolume, placed outside of the body, or inserted into the subject volumein order to provide a plurality of reference points within the volume.Although illustrated as being towards the distal tip of the catheters204, it will be appreciated that the reference transducers 202 arecapable of being disposed at any point along the length of the referencecatheters 204.

The location element 168(1) is preferably in operable connection with anultrasound transceiver 206. The reference transducers 202 are preferablycoupled to an ultrasound transceiver 208. The location processor 108 iscoupled to both of the ultrasound transceivers 206, 208. In analternative embodiment, the location element 168(1) and the referencetransducers 202 may be coupled to a single ultrasound transceiver,thereby eliminating the need for two ultrasound transceivers. In anotherembodiment, the location processor 108 may incorporate the ultrasoundtransceivers, thereby eliminating the need for separate transceivers206, 208.

Returning to FIG. 5, the location processor 108 preferably includescontrol circuits that cause the location element 168(1) and thereference transducers 202 to vibrate and produce ultrasound waves, bycontrolling the transceivers 206, 208. For example, the transceivers206, 208 transmit and receive the ultrasonic signals that are sent toand received from the location element 168(1) and the. transducers 202.

The ultrasound signals that are transmitted by the location element168(1) and the transducers 202 travel through the patient's body.Subsequently, a portion of the signals generated by the location element168(1) will be reflected back from a bodily structure and impinge, i.e.,be received by, the location element 168(1). These signals are not,however, processed because location element 168(1) is not in listeningmode at this time. Transducers 202 are, however, in listening mode. Whenin listening mode, the location element 168(1) will also receiveultrasound signals that were generated by the transducers 202. Thelocation element 168(1) generates electrical signals corresponding tothe ultrasound signals received from transducers 202, and then transmitsthe electrical signals back to the location processor 108 via theultrasound transceiver 206. In a like manner, the transducers 202 willreceive signals generated by the location element 168(1). Thetransducers 202 are also capable of generating electrical signalsrepresenting the received signals and transmitting the⁻electricalsignals back to the location processor 108 via transceiver 208.

The location processor 108 analyzes electrical signals corresponding toultrasound signals received by both the location element 168(1) and thereference transducers 202 in order to triangulate the position andorientation of the location element 168(1). The location processor 108preferably uses an algorithm that compensates for the known velocity ofsound in the blood pool when making the calculations, if referencetransducers 202 are placed within the body along with the locationelement 168(1). Using these calculations, the location processor 108employs triangulation methods and determines a precise three-dimensionallocation and orientation, i.e., an absolute location, of the locationelement 168(1) with respect to the three-dimensional coordinate systemthat is provided by the reference transducers 202. Preferably, thelocation processor 108 performs these calculations on a continual basisin order to enable the real time tracking of the location element 168(1)within the patient's body.

Further examples of ultrasonic triangulation techniques and systemssuitable for implementation with the precise location tracking subsystemare disclosed in U.S. Patent No. 6,027,451, entitled “Method andApparatus for Fixing the Anatomical Orientation of a DisplayedUltrasound Generated Image,” and U.S. Pat. No. 6,070,094, entitled“Systems and Methods for Guiding Movable Electrode Elements WithinMultiple-Electrode Structures,” which are expressly and fullyincorporated herein by reference.

In another embodiment, shown in FIG. 6, magnetic field locatingtechniques are utilized by the location processor 108 to track theabsolute position of a location element 168(2). Here, the locationelement 168(2) may be a magnetic sensor, and is preferably an array ofmagnetic sensors. For example, the location element 168(2) may be anarray of three or six magnetic coil sensors, with each coil sensororiented to provide one of the x, y, z, yaw, roll, and pitch coordinatesfor the location element 168(2). Additionally, the location element168(2) may be separate from the treatment element 168, as illustrated inFIG. 6, or the treatment element 168 may incorporate a magnetic sensor,thereby eliminating the need for a separate and discrete locationelement 168(2). Reference magnetic sensors 212 are placed either in thesubject volume, on the body, or on some location outside of the body.When placed within the subject volume, each reference sensors 212 ispreferably disposed on a distal end of a reference catheter 214.

An antenna 215 transmits magnetic fields that are received by thesensors. The antenna 215 is coupled to a magnetic field generator 216.The magnetic field generator 216 originates the signals that the antenna215 transmits to the location element 168(2) and the reference sensors212. The magnetic field generator 216 is preferably coupled to locationprocessor 108, which controls the operation of generator 216.

In a preferred embodiment, the antenna 215 transmits three orthogonalmagnetic fields. The location element 168(2), in this embodiment,comprises a plurality of coils configured to detect the orthogonalmagnetic fields transmitted by antenna 215. After detecting theorthogonal magnetic fields transmitted by antenna 215, location element168(2) transmits a signal to magnetic field strength detector 218. Themagnetic field strength detector 218 may be a separate unit that iscoupled to the location processor 108. In another embodiment, however,the magnetic field strength detector 218 may be implemented as anintegral portion of the location processor 108, rather than as aseparate unit. The magnetic field strength detector 218 relays thesignal received from the location element 168(2) to the locationprocessor 108.

The location processor 108 employs an algorithm to compute the distancevector between the center of the antenna 215 and the location element168(2). The location processor 108 preferably bases this calculation onthe signal received by the location element 168(2) and the signaltransmitted by the antenna 215. The vector is deconstructed into its x,y, and z components, as well as pitch, roll, and yaw data, in order tocompute the coordinates and orientation of location element 168(2). Thelocation processor 108 preferably performs the aforementionedcalculations continually, and on a real-time basis. Additionally, thelocation processor 108 may analyze signals from a number of referencesensors 212 in order to minimize the effects of any motion artifacts onthe localization of location element 168(2). As illustrated, thereference sensors 212 are disposed on reference catheters 214 that maybe inserted within the body or placed outside the body. Alternatively,the sensors 212 may be placed on an external surface of the body or on afixed point away from the body entirely. Furthermore, although FIG. 6shows two reference catheters 214, each having one reference sensor 212,a smaller or larger number than two reference catheters 214 may be usedto vary the degree to which the localization of the location element168(2) is refined. Additionally, each reference catheter 214 mayincorporate more than one reference sensor 212 in order to furtherrefine the localization of the location element 168(2) or to provideenough data to compute the curvature of the catheter 162. For example,if three location elements 168(2) are placed at certain points alongcatheter 162 then a circle that approximates the catheter curvature canbe fitted through these three points. The reference sensors 212 arepreferably coupled to magnetic field strength detector 218 and transmitsignals, corresponding to received magnetic fields, to the detector 218.The detector 218 is configured to transmit these signals to the locationprocessor 108 in substantially the same manner as previously describedwith the relay of signals from the location element 168(2). TheseCalculations are preferably performed continually and in real time.

Regardless of whether the location processor 108 utilizes magnetic orultrasonic waves in determining the location of the location element168, the location processor 108 provides the positional location datafor the location element 168 to the registration processor 110 of theregistration subsystem 102. The registration processor 110 is configuredto calculate the position of the treatment element 164 based upon thepositional data for the location element 168, register that positionaldata in the three-dimensional coordinate system, and store thepositional data for the treatment element 164 in memory 104. Calculatingthe positional location data for the treatment element 164 in thismanner is possible since the location element 168 is placed in closeproximity to, or is incorporated in, the treatment element 164.Alternatively, the positional location data for the treatment element164 can be calculated based upon the position of the location element168 and the distance between the location element 168 and the treatmentelement 164. The registration subsystem 102 is configured to output thelocation of the treatment element 164 on display 106.

The implementation of the location elements 128 and 148 within theregistration subsystem 102, and the manner in which the imaging element124 and mapping elements 144 are respectively located, is similar to theimplementation of the location clement 168 within the registrationsubsystem 102 and the manner in which the treatment element 164 islocated, as just described, and will thus not be discussed in furtherdetail for purposes of brevity.

5. Overall Operation of the System

One preferred method of operating the system 100 will now be described.Turning to

FIG. 7 a, the imaging device 122 having an ultrasonic transducer 124 isintroduced into the subject volume SV using known techniques. Forexample, in one process, a transeptal deployment is utilized. For aprocedure in the left atrium using the transeptal deployment, forexample, the sheath 147 is first maneuvered into the right atrium. Anopening is made through the septum, and the sheath 147 is advanced intothe left atrium. The imaging device 122 is then routed through thesheath 147 and into the left atrium. Preferably, the opening is as smallas possible, but large enough to allow the passage therethrough of theimaging device 122, via the sheath 147.

The user maneuvers the imaging device 122 in the volume SV until thedistal tip touches a distal wall that defines the subject volume SV. Theuser operates the imaging subsystem 120 to gather image data regardingthe subject volume SV. As previously noted, in an embodiment of theimaging subsystem 120 that implements a pull-back approach, multipletwo-dimensional image slices of the subject volume SV are gathered. Thepullback can be along a rectilinear or curved trajectory. If thetrajectory is curved then, in order to determine the curvature, it ispreferable to have more than three location elements placed on theimaging device 122. Additionally, the image slices are preferablygathered at the same relative time, such as at the same point in thecardiac cycle. To form four-dimensional images, sets of image slices aregathered. The sets of image slices may be sets of thirty images, for athirty frame per second imaging rate, or sixty images, for a sixty frameper second imaging rate. The imaging subsystem 120 provides the imagedata to the registration processor 110 of the registration subsystem102.

As illustrated in FIG. 7 a, the location processor 108 uses ultrasoundto track the position of the location element 128 (which in this casewill be an ultrasound location element) of the imaging device 122, andreference transducers 202 are used to provide reference points for thelocation processor 108. The user may place reference transducers 202within the subject volume SV, as well as outside the body. As shown inFIG. 7 b, magnetic fields are used by the location processor 108 (whichin this case will be a magnetic location element) to track the locationelement 128, and the user places the antenna 215 at some point outsidethe body to provide a reference signal. The user may also introducereference sensors 212 into the subject volume SV, or place referencesensors 212 outside the body, to refine the localization of locationelement 128. With either process, the reference transducers 202, or thereference sensors 212 and antenna 215, are preferably left in place forthe other steps of the process to allow for additional locating of thelocation elements 148 and 168.

After receiving the position of the location element 128 on the imagingdevice 122 from the location processor 108, the registration processor110 registers the image data to a three-dimensional coordinate system,stores the registered image data in memory 104, and eventually presentsthe image data, as a reconstructed three-dimensional or four-dimensionalrepresentation of the subject volume SV, on display 106. For example, inone process, the imaging device 122 is left within the volume SV duringthe following steps, and provides continually updated image dataregarding the subject volume SV to the imaging subsystem 120, whichrelays that data to the registration processor 110 of the registrationsubsystem 102. The registration subsystem 102 then updates thereconstructed image of the subject volume SV as the updated image datais provided. The registration subsystem 102 presents the reconstructedrepresentation in four-dimensions, i.e., the image is dynamic. With adynamic four-dimensional image of the heart, for instance, activitiessuch as the closure and opening of valves and vessels, atrio-septaldefects, and atrio-septal defect closure plugs are displayed in animatedform to the user.

In another aspect of the method, the imaging device 122 is removed fromthe volume SV prior to the following steps. The following steps maystill be accomplished by reference to the previously acquired, andregistered, three-dimensional or four-dimensional image.

In another preferred embodiment, the imaging device 122 is a real-timethree-dimensional imaging device such as an optical camera or athree-dimensional real-time ultrasound catheter. Such embodiment doesnot necessarily require the pullback step because it already providesthree-dimensional renderings of the volume SV real-time. If imaging ofextended portions of the volume SV is required then pullback of thereal-time imaging device may be necessary. As in the previousembodiment, one or more location elements 128 may be placed on theimaging device.

In addition to gathering and processing image data regarding the subjectvolume SV, the system 100 is used to acquire and process mapping dataindicating any target sites for treatment within the subject volume SV.Turning to FIGS. 8 a and 8 b, the mapping device 142 is introduced intothe subject volume SV. Specifically, the mapping device 142 is insertedthrough the sheath 147, and therefore the opening, through which theimaging device 122 was originally inserted.

Initially, the mapping device 142 is introduced into the subject volumeSV with the sheath 147 (see FIG. 3) covering the structure 145. Afterthe user places the mapping device 142 at a desired location in thesubject volume SV, the sheath 147 is moved proximally to allow thestructure 145 to expand. This results in the mapping elements 144 beingplaced in contact with tissue. The map processor 146, which is coupledto the mapping device 142, is then operated to receive and analyze dataregarding tissue surrounding the mapping elements 144. After receivingthe mapping data, the map processor 146 relays the mapping data to theregistration processor 110 of the registration subsystem 102.Additionally, the location processor 108 provides the location oflocation elements 148 within the three-dimensional coordinate system tothe registration processor 110. FIG. 8 a illustrates the use of thelocation processor 108 that uses ultrasound to determine the positionsof the location elements 148, whereas FIG. 8 b illustrates the use ofthe location processor 108 that uses magnetic fields to determine thepositions of the location elements 148. After receiving the positionaldata for the location elements 148, the registration processor 110registers the mapping data in the same three-dimensional coordinatesystem within which the processor 110 registered the image data from theimaging subsystem 120. The registration processor 110 may store theregistered mapping data within memory 104. As illustrated in FIGS. 8 aand 8 b, the registration processor 110 then displays the registeredmapping data, along with the image data, i.e., the reconstructed imageof the subject volume, on the display 106.

In one aspect of this method, the mapping data is superimposed over areconstructed three-dimensional image of the subject volume. In anotheraspect of this method, the mapping data is superimposed over areconstructed four-dimensional image of the subject volume. FIG. 10illustrates a reconstructed three-dimensional image 302 of the subjectvolume having superimposed thereon target point data, which arerepresented by discrete points X. FIG. 11 illustrates a reconstructedthree-dimensional image 304 of the subject volume having superimposedthree-dimensional mapping data where the positional data is displayed invarious colors (shown as different shades). Each color represents thetime delays sensed by the mapping elements 144, and a user is able toidentify' a target site based on a particular color, or pattern of colorsuch as a swirling pattern. Alternatively, the mapping data can befour-dimensional, i.e., dynamical three-dimensional mapping data thatchanges over time. FIG. 11 also shows the relative positions of thesplines 148 of the mapping device 142 with the letters A through F. Afour-dimensional reconstructed image having three-dimensional mappingdata superimposed thereon would look similar to FIG. 10 and FIG. 11,respectively, but the image would be animated.

Reference is now made to FIGS. 9 a and 9 b, which shows the processeswherein the location processor 108 utilizes ultrasound (FIG. 9 a) ormagnetic fields (FIG. 9 b) to determine the location of location element168 for purposes of navigating the treatment device 162. To guide a userin placing a treatment device 162, and specifically a treatment element164 on the device 162, at a target site for delivering treatment, theregistration processor 110 simultaneously displays the mapping data, thereconstructed image of the subject volume, and the location of thetreatment element 164 within the volume on the display 106.Alternatively, the mapping data may not be necessary to be displayed ifthe user targets certain anatomic aspects of the subject volume SV. Byreference to the display 106, the user is able to maneuver the treatmentelement 164 to a target site, indicated by the displayed mapping data orby another type of target, such as an anatomic landmark.

First, the treatment device 162 is introduced into the subject volumeSV. For either of the methods shown in FIG. 9 a or 9 b, positional datafor the location element 168 is continually provided to the locationprocessor 108 as the treatment device 162 is moved within the subjectvolume SV. The location processor 108, in turn, provides the positionaldata for the location element 168 to the registration processor 110. Aspreviously discussed, the registration processor 110 determines thepositional data for the treatment element 164 based upon the positionaldata for the location element 168, registers the positional data for thetreatment element 164, and display the positional data on a display 106along with the reconstructed image of the volume SV and, if necessary,the mapping data.

The registration subsystem 102 continually updates the positional datafor the treatment element 164 on the display 106, using theaforementioned steps, as positional data for the location element 168 isprovided by the location processor 108. By reference to the combineddisplay of the reconstructed three-dimensional or four-dimensional imagedata, the optional three-dimensional or four-dimensional mapping data,and the positional data for the treatment element 164 on the display106, the user places the treatment element 164 at a target site.Alternatively, the user may guide the treatment element 164 by onlyreferencing the combined display of the mapping data and the treatmentelement 164. Optionally, the positional data of the treatment element164 can be stored in memory 104, and then recalled and displayed on thedisplay 106, so that the physician can view the trajectory of thetreatment element 164 as it is moved within the subject volume SV. Oncethe user or physician positions the treatment element 164 adjacent atarget site, the user or physician is then able to operate the treatmentdelivery source 166 to deliver treatment to the site. Also, thetreatment element 164 maybe a therapeutic agent delivery element, ratherthan an ablation element. In this case, the user delivers a therapeuticagent rather than ablation energy to the target site X. All of the otherprocessing steps with regard to reconstructing a three-dimensional orfour-dimensional image of the subject volume SV, or determining thethree-dimensional or four-dimensional mapping data within the volume SV,and guiding a user in maneuvering the treatment element 164 to a targetsite apply equally irrespective of whether the treatment element 164 isan ablation element or a therapeutic agent delivery element.

Returning to the methods shown in FIGS. 9 a and 9 b, wherein thetreatment delivery source 166 includes the ablation power source 163,the user operates the treatment delivery source 166 to controllablydeliver ablation energy to target sites. Specifically, the treatmentdelivery source 166 comprises set point parameters, which can beadjusted when the treatment delivery source 166 is in standby mode. Theset point parameters include, among others, the magnitude of theablation power delivered to the tissue, the desired tissue temperature,and the duration of ablation power delivery.

To this end, the ablation power delivered by the treatment deliverysource 166 is set using the power control input 65 coupled to thecontrol circuit 161. The actual ablation power delivered by thetreatment delivery source 166 is reported by the power meter 61. Duringablation energy delivery, based upon input received from the powercontrol input 65, the control circuit 161 adjusts power output tomaintain an actual measured temperature at the temperature set point.The desired temperature to which the ablated tissue is exposed is setusing a temperature control input 67 coupled to the control circuit 161.The actual temperature to which the ablated tissue is exposed, which isobtained from the temperature sensor 167, is reported by the temperaturegauge 68, or output on display 106.

The desired duration of ablation power applied is set using the timerinput 66. The clock 165 tracks the elapsed time from initial delivery ofablation power to the tissue, and counts from zero to the set pointduration. The elapsed time is displayed on counter 69. The user placesthe treatment delivery source 166 in deliver mode by depressing theablation power control button 62 to place the source 166 in a power “on”orientation. When in the deliver mode, the treatment delivery source 166delivers ablation energy to the tissue in contact with the treatmentelement 164 until the count displayed by the clock 165 reaches the setpoint duration or until the power control button 62 is depressed into apower “off” orientation.

In the illustrated embodiment, the treatment delivery source 166operates in a monopolar mode. To properly operate in this mode, anindifferent electrode 63, which is coupled to the treatment deliverysource 166, is attached to the patient's back or other exterior skinarea. When operated in the monopolar mode, ablating energy is emittedbetween the treatment element 164 and the indifferent electrode 63.Alternatively, when the treatment delivery source 166 is operated in abipolar mode there is no indifferent electrode 63.

As previously discussed, further details on the use and structure of asuitable treatment delivery source are disclosed in U.S. Pat. No.5,383,874 to Jackson, et al., which has been expressly and flatlyincorporated herein by reference.

6. System with External Imaging

Although the previously described treatment system 100 utilizes aninternal imaging probe 122 in order to image the region of interest fromthe inside of the subject volume SV, an external imaging device can beused as well. For example, referring to FIG. 12, a treatment system 300will now be described. The treatment system 300 is similar to thetreatment system 100, with the exception that it, utilizes an externalimaging device 322 to provide images of the subject volume SV. Asexamples, the imaging device 302 can be a computerized axial tomography(CT) device or a magnetic resonance imaging (MRI) device, which can taketwo-dimensional image slices of the tissue, and then reconstruct theseslices into a three-dimensional images of the tissue. For example, theslice images could be stored in the Diacom format and thethree-dimensional renderings could be constructed using software sold byTomTec Imaging Systems, located in Germany. The imaging device 322 canbe located within the operating room where the therapeutic treatment isperformed, or can be remotely located, in which case, the imaging device322 can be networked within the treatment system 300. The imaging device322 can even generate the image off-line (e.g., a day before treatment),in which case, the image can be downloaded to the pertinent componentsof the treatment system 300, or can even be transferred using a suitableportable medium, such as a digital storage disk.

The treatment system 300 also comprises a registration subsystem 302that is similar to the previously described registration subsystem 102in that it includes a registration processor 310, which with theassistance of the location processor 108 and location elements 128associated with the mapping elements 144 and treatment element 164,registers the mapping data acquired from the mapping subsystem 140 andthe therapeutic element 164 within the three-dimensional coordinatesystem.

The registration subsystem 302 differs from the registration subsystem102 in that it registers the image date acquired from the externalimaging device 322 using location elements 128 that are distributed onthe patient's body so that they intersect the imaging beam from theexternal imaging device 322. For example, if the subject volume is theheart, the location elements 128 can be suitable affixed on the chest ofthe patient or even within the heart itself. In this manner, thelocation elements 128 show up on the image as fiducial points that canbe used to register the externally acquired image within thethree-dimensional coordinate system. In particular, the locationprocessor 108 determines the locations of the location elements 128distributed on the patient's body, and then the registration processor310 registers the three-dimensional image acquired by the externalimaging device 322 by aligning the fiducial points contained in theimage with the locations of the location elements 128 acquired by thelocation processor 108.

Alternatively, rather than distributing the location elements 128 on thepatient's body to produce fiducial points on the three-dimensionalimage, location information of the subject volume SV can be acquiredusing a roving probe (e.g., the treatment device 162 or a dedicatedprobe) with a location element 128. In particular, the location element128 of the roving probe can be placed in various locations within thesubject volume SV, so that a number of points (e.g., 20) can be taken.Using known techniques, the registration processor 310 can then fit thethree-dimensional image to the acquired points.

For example, assume that the 3-D surface obtained from the externalimaging device 322 consists of a set of points P_(i)(x, y, z):

SV ₃₂₂ ={P _(i)(x, y, z)|i=1 . . . N}

Also, assume that the user obtains a second set of points Rj(x, y, z) bymoving the roving probe within the subject volume:

SV _(rv) ={R _(j)(x, y, z)|j=1 . . . M}

The distance from a point Rj to the surface SV₃₂₂ can be defined as:

D _(j)=min(dist(R _(j) , P _(i))|i=1 . . . N)

In order to register the surface SV₃₂₂ in the (x, y, z) space, a seriesof rotations and translations can be performed to best match thissurface onto the set of R_(j) points. Preferably, the series ofgeometrical transformations are done such that a cost function isminimized. The following are examples of applicable cost functions:

C ₁=1/M*sum(D _(j) , j=1 . . . M)

C ₂=1/M*sqrt(sum(D _(j) ² , j=1 . . . M))

Other cost functions could be used. Then the transformations can beiterated using known adaptation techniques. For example, methods such asthe steepest descent, gradient-based, least-squares or recursiveleast-squares adaptation may be employed. Such methods are described indetail in S. Haykin, Adaptive Filter Theory. Englewood Cliffs, NJ:Prentice Hall, 1991.

Alternatively, the operator can even manually fit the three-dimensionalimage to the acquired points. In this case, at least some of theacquired points can correspond to known anatomical locations within thesubject volume SV. For example, of the volume SV is a heart, the knownanatomical locations can be the openings to the pulmonary veins, theright ventricular apex, the mitral valve, etc. In this manner, theoperator can more efficiently and easily fit the image to the points.

Although particular embodiments of the present inventions have beenshown and described, it will be understood that it is not intended tolimit the present inventions to the preferred embodiments, and it willbe obvious to those skilled in the art that various changes andmodifications may be made without departing from the spirit and scope ofthe present inventions. Thus, the present inventions are intended tocover alternatives, modifications, and equivalents, which may beincluded within the spirit and scope of the present inventions asdefined by the claims.

1.-111. (canceled)
 112. A system for navigating within a body cavity ofa patient, comprising: an imaging subsystem comprising an imaging deviceconfigured for generating image data of the body cavity; a probeconfigured to be moved within the body cavity; and a three-dimensionalcoordinate registration subsystem configured for registering the imagedata and the location of the probe within a three-dimensional coordinatesystem.
 113. The system of claim 112, wherein the probe comprises atreatment device having a treatment element, the system furthercomprising a treatment delivery subsystem comprising the treatmentdevice and a treatment delivery source coupled to the treatment element.114. The system of claim 112, wherein the probe comprises a mappingdevice configured for generating mapping data, the system furthercomprising a mapping subsystem comprising the mapping device, whereinthe registration subsystem is further configured for registering themapping data within the three-dimensional coordinate system.
 115. Thesystem of claim 112, further comprising a display coupled to theregistration subsystem.
 116. The system of claim 112, wherein theimaging device is an internal imaging device.
 117. The system of claim112, wherein the imaging device is an external imaging device.
 118. Thesystem of claim 112, wherein the imaging device is an ultrasound imagingdevice.
 119. The system of claim 112, wherein the imaging device is areal-time 3-D ultrasound catheter.
 120. The system of claim 112, whereinthe imaging device is a computerized axial tomography device.
 121. Thesystem of claim 112, wherein the imaging device is a magnetic resonanceimaging device.
 122. The system of claim 112, wherein the body cavitycomprises a heart chamber.
 123. The system of claim 112, wherein theregistration subsystem is configured for registering the image data bydetermining a position of a source of the image data within thethree-dimensional coordinate system, and aligning the image data so thatthe image data source is coincident with the determined position. 124.The system of claim 112, wherein the registration subsystem isconfigured for registering the image data by generating fiducial pointswithin the image data, determining positions of the fiducial pointswithin the three-dimensional coordinate system, and aligning the imagedata so that the fiducial points are coincident with the determinedpositions.
 125. The system of claim 112, wherein the registrationsubsystem is configured for registering the image data by generating aset of points, determining positions of the points within thethree-dimensional coordinate system, and best fitting the image data tothe set of points.
 126. The system of claim 112, wherein theregistration subsystem is configured for registering the image data byat least partially allowing input from a user.